Clarence I. Kado

The T-pilus of Agrobacterium tumefaciens

T-pilus biogenesis uses a conserved transmembrane nucleoprotein- and protein-transport apparatus for the transport of cyclic T-pilin subunits to the Agrobacterium cell surface. T-pilin subunits are processed from full-length VirB2 pro-pilin into a cyclized peptide, a rapid reaction that is Agrobacterium specific and can occur in the absence of Ti-plasmid genes.

Small, stable shuttle vectors for use in Xanthomonas

Plasmids from three broad-host-range (bhr) incompatibility groups (Inc) were evaluated for use as cloning vectors in Xanthomonas campestris pv. malvacearum (Xcm), the causal agent of bacterial blight of cotton. The IncP vectors pLAFR3 and pVK102 could not be introduced into Xcm at a significant frequency (less than 1 x 10(-10] and IncQ vectors such as pKT210 were unstable in their maintenance and tended to delete cloned inserts. IncW vectors such as pSa747 also were lost readily from Xcm in the absence of selection pressure. We constructed two plasmids, pUFR027 and a cosmid derivative, pUFR034, which have proven useful as cloning vectors in Xcm and other xanthomonads. They contain the pSa origin of DNA replication, the partition locus parA from the Agrobacterium plasmid pTAR, a neomycin-resistance selection marker, and alacZ alpha cassette with cloning sites. pUFR027 is 9.3 kb, and pUFR034 is 8.7 kb in size. They can be mobilized by conjugation into Xcm at a frequency of approx. 1 x 10(-6) per recipient and are maintained stably (greater than 95% retention over 36 generations without selection pressure) in both broth culture and in planta. The plasmids were introduced and maintained stably in X. citri, and in X. campestris pathovars campestris, citrumelo, vesicatoria and translucens, and were moderately stable in X. phaseoli. No effects of the plasmids on pathogenicity have been observed.

Genetic and environmental factors affecting T-pilin export and T-pilus biogenesis in relation to flagellation of Agrobacterium tumefaciens.

The T pilus, primarily composed of cyclic T-pilin subunits, is essential for the transmission of the Ti-plasmid T-DNA from Agrobacterium tumefaciens to plant cells. Although the virB2 gene of the 11-gene virB operon was previously demonstrated to encode the full-length propilin, and other genes of this operon have been implicated as members of a conserved transmembrane transport apparatus, the role of each virB gene in T-pilin synthesis and transport and T-pilus biogenesis remained undefined. In the present study, each virB gene was examined and was found to be unessential for T-pilin biosynthesis, except virB2, but was determined to be essential for the export of the T-pilin subunits and for T-pilus formation. We also find that the genes of the virD operon are neither involved in T-pilin export nor T-pilus formation. Critical analysis of three different virD4 mutants also showed that they are not involved in T-pilus biogenesis irrespective of the A. tumefaciens strains used. With respect to the environmental effects on T-pilus biogenesis, we find that T pili are produced both on agar and in liquid culture and are produced at one end of the A. tumefaciens rod-shaped cell in a polar manner. We also report a novel phenomenon whereby flagellum production is shut down under conditions which turn on T-pilus formation. These conditions are the usual induction with acetosyringone at pH 5.5 of Ti-plasmid vir genes. A search of the vir genes involved in controlling this biphasic reaction in induced A. tumefaciens cells revealed that virA on the Ti plasmid is involved and that neither virB nor virD genes are needed for this reaction. The biphasic reaction therefore appears to be mediated through a two-component signal transducing system likely involving an unidentified vir gene in A. tumefaciens.

Characterization of flagella genes of Agrobacterium tumefaciens, and the effect of a bald strain on virulence

Agrobacterium tumefaciens produces flagella that are arranged circumthecally near one end of the bacilliform cell. The flagella are required for motility to facilitate reaching the root surface, and possibly aid in orientating the bacterial cells at various sites for infection. We have identified three flagella genes designated flaA, flaB, and flaC. Mutations in flaA, flaB and flaC result in abberant swimming behaviour. Electron microscopic examination of these mutants revealed the defective flagella. A non‐motile, bald mutant strain was generated by deleting all three fla genes. Nucleotide sequencing of flaA, flaB, and flaC showed that they have a potential coding capacity for polypeptides of 307, 321, and 314 amino acid residues, respectively. The predicted amino acid sequences of the A. tumefaciens FlaA and FlaB proteins are similar (66% average identity) to the FlaA and FlaB proteins encoded by flaA and flaB genes, respectively, in Rhizobium meliloti. There was no counterpart FlaC protein reported in R. meliloti, but the A. tumefaciens FlaC is similar in amino acid sequence to the R. meliloti FlaA (59.8% identity) and FlaB (66.7% identity). Distinct from FlaA and FlaB of R. meliloti is the absence of histidine and cysteine residues and their shorter length (by 88 amino acid residues fewer than FlaA and FlaB of R. meliloti ). The transcriptional start sites of each fla gene determined by primer extension revealed consensus‐sequence boxes representing potential binding sites for σ28 RNA polymerase (RNAP) upstream of the transcriptional start of each fla gene. Besides the potential σ28‐binding site upstream of flaC, also present are additional putative conserved sequences, GC at −11 and GG at −21 from the transcriptional start, that resemble potential binding motifs for σ54. Because the σ54 promoter is associated with genes regulated by physiological changes in various bacteria, the flaC gene might be similarly regulated in response to A. tumefaciens responding to host plant stimuli. Virulence studies showed that the bald strain was consistently reduced in virulence below that of the parental wild‐type strain by at least 38%. The difference is statistically significant and suggests that the flagella may play a role in facilitating virulence.

DNA transfer fromAgrobacterium toZea mays orBrassica by agroinfection is dependent on bacterial virulence functions

SummaryDNA transfer fromAgrobacterium tumefaciens, a soil bacterium, to the non-host graminaceous monocotyledonous plantZea mays, was analysed using the recently developed technique of agroinfection. Agroinfection ofZ. mays with maize streak virus using strains ofA. tumefaciens carrying mutations in the pTiC58 virulence region showed an almost absolute dependence on the products of the bacterialvirC genes. In contrast, agroinfection of the control hostBrassica rapa with cauliflower mosaic virus was less dependent on thevirC gene products. In other respects, the basic mechanism of the plant-bacterium interaction was found to be similar. While intactvirA, B, D and G functions were absolutely necessary, mutants invirE were attenuated. Agroinfection of maize was effective in the absence of an exogenously suppliedvir gene inducer, and indeed woundedZ. mays tissues were found to produce substance(s) which induced the expression ofA. tumefaciens vir genes. These findings are discussed in the light of current knowledge about the function ofAgrobacterium vir genes.

An inner-membrane-associated virulence protein essential for T-DNA transfer from Agrobacterium tumefaciens to plants exhibits ATPase activity and similarities to conjugative transfer genes

The 9.5kb virB operon is the largest of the six major operons in the Ti plasmid vir region. This operon contains eleven genes, the largest of which is virB4. This gene encodes an 84kDa protein whose function has not been identified. Its roles in conferring virulence on Agrobacterium tumefaciens and in the T‐DNA transfer process were determined by generating non‐polar mutants by using the Tn5pvirB transposon in which the virB promoter is transcribed downstream of its position of insertion. Several independent mutants were isolated and each insertion site in virB4 was confirmed by nucleotide sequence analysis. These mutants were tested for T‐DNA transfer ability by agroinfection and for tumorigenicity by inoculation in Brassica and Datura. All mutants were agroinfection‐ and tumorigenicity‐negative. These data strongly suggest that virB4 is essential for both the interkingdom transfer of the T‐DNA and virulence. Furthermore, by using anti‐VirB4 serum, the protein product of virB4 was localized to the inner‐membrane fraction of A. tumefaciens. Purified VirB4 protein hydrolyses ATP and this activity was quenched by the anti‐VirB4 serum. The energy generated by VirB4 ATPase therefore may be used to transfer T‐DNA or to assemble the T‐DNA transfer apparatus on the bacterial membrane. Protein sequence analyses revealed striking similarities between VirB4 protein and the proteins required for conjugative transfer, which include TraC, TrwK, and TrbE of plasmids F, R388, and RP4, repectively. These findings suggest that VirB proteins play a direct role in the assembly of a conjugative transfer apparatus required for the transfer of the T‐DNA from A. tumefaciens to plant cells.

Molecular characterization of the vir regulon of Agrobacterium tumefaciens: Complete nucleotide sequence and gene organization of the 28.63-kbp regulon cloned as a single unit

The entire vir regulon of Agrobacterium tumefaciens was subcloned and the complete 28.6-kbp nucleotide sequence was determined. The regulon was cloned as a single unit into two replicons, one of which replicates at a high copy number in this bacterium, and a second which has broad-host-range features to replicate in other Gram-negative bacteria. These vir region plasmids are able to confer in trans the processing and transfer activities on a second plasmid containing the T-DNA. In the high copy number vir region plasmid pUCD2614, a moderate increase in basal vir gene expression was observed as judged by virE::cat fusion expression assays relative to the wild-type control plasmid. Furthermore, higher efficiencies of tobacco leaf disk transformation were observed than with the widely used vir helper plasmid pAL4404. The nucleotide sequence studies showed that the vir region consists of 28,631 bp comprising 24 open reading frames which encode proteins involved in tumorigenicity. Two open reading frames not previously characterized, virH and ORF5, were uncovered within the virD/virE intervening spacer region. Together these studies more completely characterize the structure and function of the vir regulon.

Promiscuous DNA transfer system of Agrobacterium tumefaciens: role of the virB operon in sex pilus assembly and synthesis.

Conjugative transfer of DNA that occurs between bacteria also operates between bacteria and higher organisms. The transfer of DNA between Gram‐negative bacteria requires initial contact by a sex pilus followed by DNA traversing four membranes (donor plus recipient) using a transmembrane pore. Accumulating evidence suggests that transfer of the T‐DNA from Agrobacterium tumefaciens to plants may also occur via a conjugative mechanism. The virB operon of the Ti plasmid exhibits close homologies to genes that are known to encode the pilin subunits and pilin assembly proteins. The proteins encoded by the PilW operon of IncW plasmid R388 share strong similarities (average similarity=50.8%) with VirB proteins. Similarly, the TraA, TraL and TraC proteins of IncF plasmid F have similarities to VirB2, VirB3 and VirB4 respectively (average similarity = 45.3%). VirB2 protein (12.3 kDa) contains a signal peptidase‐I cleavage sequence that generates a polypeptide of 7.2 kDa. Likewise, the 12.8 kDa propilin protein TraA of plasmid F also possesses a peptidase‐I cleavage site that generates the 7.2 kDa pilin structural protein. Similar amino acid sequences of the conjugative transfer genes of F, R388 as well as plasmid RP4 and the genes of the ptl operon of Bortedella pertussis suggest the existence of a superfamily of transmembrane proteins adapted to the promiscuous transfer of DNA‐protein complexes.

Design and development of amplifiable broad-host-range cloning vectors: Analysis of the vir region of Agrobacterium tumefaciens plasmid pTiC58

The construction of a set of new plasmids that are suitable as general cloning vectors in Escherichia coli and Agrobacterium tumefaciens is described. Plasmid pUCD2 is amplifiable in E. coli, replicates in a wide range of gram-negative hosts and contains a number of useful restriction endonuclear cleavage sites and antibiotic resistance genes. This includes unique sites for KpnI, SacI, SacII, PstI, ClaI, SalI, EcoRV, and PvuII and the genes for resistance to kanamycin, tetracycline, ampicillin, and spectinomycin/streptomycin. Derivatives of pUCD2 include pUCD4, which has a unique XbaI site and the cosmid pUCD5, which also contains a unique EcoRI site. Two smaller plasmids pUCD9P and pUCD9X, contain many of the same unique sites as pUCD2 and pUCD4, but carry only the pBR322 replication origin and therefore do not display the extensive host-range of pSa. These plasmids were used to isolate and manipulate fragments of the A. tumefaciens pTiC58 plasmid in both E. coli and A. tumefaciens. Fragments from the virulence (vir) region of pTiC58 inserted immediately upstream of the spectinomycin resistance gene of pUCD2 resulted in spectinomycin resistance levels that varied greatly depending on the particular fragment and its orientation of insertion. Using this property we find that a major portion of the vir region of pTiC58 is transcribed in A. tumefaciens and E. coli from left to right toward the T region.

Biogenesis of T Pili in Agrobacterium tumefaciens Requires Precise VirB2 Propilin Cleavage and Cyclization

VirB2 propilin is processed by the removal of a 47-amino-acid signal peptide to generate a 74-amino-acid peptide product in both Escherichia coli and Agrobacterium tumefaciens. The cleaved VirB2 protein is further cyclized to form the T pilin in A. tumefaciens but not in E. coli. Mutations in the signal peptidase cleavage sequence of VirB2 propilin cause the formation of aberrant T pilin and also severely attenuate virulence. No T pilus was observed in these mutants. The potential role of the exact VirB2 propilin cleavage and cyclization in T pilus biogenesis and virulence is discussed.